Wireless strain gauge/flow sensor

ABSTRACT

A flow rate sensor is provided in a wireless, leadless package. The flow rate sensor includes a MEMs sensor coupled to an ASIC and an antenna. The flow rate sensor is powered by radiation received from a control module adjacent the flow rate sensor. The flow rate sensor is placed within a fluid and monitors the flow rate of the fluid. The control module is not in the fluid and receives flow rate data from the flow rate sensor.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the benefit under 35 U.S.C. §119(e) of U.S.Provisional Patent Application No. 61596631 filed Feb. 8, 2012. Thisprovisional application is incorporated herein by reference in itsentirety.

BACKGROUND

1. Technical Field

The present disclosure relates to integrated sensor devices. The presentdisclosure relates more particularly to integrated fluid sensors.

2. Description of the Related Art

Fluid injection systems are utilized in a large variety of applications.Such applications include medical applications, wherein infusion pumps,syringe pumps, auto-injectors, and many other types of devices deliverfluid to a patient. Often, a particular flow rate is desired fordelivery of the fluid. For instance, medication or drugs deliveredintravenously to a patient during surgery or post-surgery typically aredelivered in very precise doses. Delivering an incorrect dose can leadto serious injury or even death. In one common technique for monitoringthe flow rate of a drug in an infusion pump, a stepper motor whichforces liquid from a reservoir through a feed line to the patient ismonitored and displacement of the fluid is calculated based ondisplacement of the stepper motor. However, such a method for monitoringthe flow rate has drawbacks in that it often does not take into accountvolumetric chamber irregularities, temperature fluctuations, fluidviscosity, atmospheric pressure and back pressure variability. Any errorin calculating the flow rate can be very harmful to the patient.

Current infusion pumps, syringe pumps, and auto-injectors lack trueclosed-loop feedback, like a flow sensor, to ensure that the correctdose size and flow rate are administered for any particular drug. Thesedevices often rely instead on calculations for dose size and flow ratedata derived from drip sensors for gravity-based pumps and screw/pistonposition sensors or load cells used in volumetric pumps. These flow rateand dose size calculation methods are subject to inherent errorsintroduced by volumetric chamber irregularities, temperature, fluidviscosity, atmospheric pressure, and back pressure variability.Additionally, and perhaps most critically, there is the potentiallyfatal human error of administering the wrong drug.

BRIEF SUMMARY

In one embodiment, a fluid dispensing system includes a control moduleand a sensor module. The sensor module is placed in direct contact withthe fluid, the fluid flow line, or the fluid container. The sensormodule is a wireless sensor module and receives power wirelessly fromthe control module. The sensor module includes a sensor coupled to anintegrated circuit die in which is formed an ASIC. The sensor is formedon a plastic or flex substrate in one embodiment. Alternatively thesensor is a MEMS sensor. The MEMS sensor and the ASIC can be formed in asingle integrated circuit die or in separate integrated circuit diescoupled together and packaged in a single package. The sensor moduleincludes an RF antenna which receives RF radiation which is thenconverted into electric energy which powers the controller and thesensor. The sensor can be a strain gauge, a pressure sensor, a flow ratesensor, or any other suitable sensor capable of measuring a desiredfluid parameter.

The control module includes a microcontroller and a transceiver. Thetransceiver emits radio frequency radiation which is received by theantenna of the sensor module. The transceiver of the control module notonly transmits energy via the RF signal, but also data. The sensormodule can be placed in contact with a fluid being dispensed. Thecontrol module is placed outside of the fluid and outside of a containercontaining the fluid but in close proximity to the sensor module.

Because the control module is in close proximity to the sensor module,the control module can provide power via RF radiation to the sensormodule. Through the MEMS flow rate sensor, the sensor module can take ameasurement of the flow rate of the fluid, and the controller canconvert the signal from the sensor to a digital signal which can then beoutput through the antenna to the transceiver of the control module. Thecontrol module can be in electrical communication with the fluiddispensing mechanism such as a stepper motor or plunger. In this way,the flow rate can be sensed and controlled in a closed-loop fashionbecause the sensor module is placed within the fluid dispensingstructure. The sensor module is disposable and requires no battery orother power. The sensor module can be inexpensively manufactured andattached within a container that contains the fluid to be dispensed, orwithin hosiery through which the fluid is dispensed.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

FIG. 1A is a block diagram of a fluid dispensing system including asensor module coupled on an inside of a fluid container according to oneembodiment.

FIG. 1B is a block diagram of a fluid dispensing system including asensor module coupled on an outside of a fluid container according toone embodiment.

FIG. 1C is a block diagram of a fluid line system including a sensormodule coupled on an inside of a fluid container according to oneembodiment.

FIG. 1D is a block diagram of a fluid line system including a sensormodule coupled on an outside of a fluid container according to oneembodiment.

FIG. 2 is a block diagram of a fluid dispensing system according to analternate embodiment.

FIG. 3 illustrates a fluid dispensing system according to oneembodiment.

FIG. 4A is a fluid container including a sensor module on an inner wallaccording to one embodiment.

FIG. 4B is a fluid container including a sensor module on an outer wallaccording to one embodiment.

FIG. 5 illustrates a syringe pump according to one embodiment.

FIG. 6 illustrates an infusion pump according to one embodiment.

FIG. 7 illustrates an insulin pump according to one embodiment.

FIG. 8 illustrates an intravenous fluid delivery system according to oneembodiment.

FIG. 9 is a block diagram of a sensor module according to oneembodiment.

FIG. 10A illustrates a sensor module prior to attachment according toone embodiment.

FIG. 10B illustrates a sensor module after attachment of an ASICaccording to one embodiment.

FIG. 11 is a cross section of a sensor module according to oneembodiment.

FIG. 12 is a block diagram of a sensor module according to oneembodiment.

FIG. 13 is a block diagram of a sensor module including a MEMS sensorand an ASIC according to one embodiment.

FIG. 14 is a cross section of a sensor module including a MEMS sensoraccording to one embodiment.

FIG. 15 is a cross section of a fluid sensor according to oneembodiment.

FIG. 16 is a flow diagram of a fluid sensing method according to oneembodiment.

FIG. 17 is a flow diagram of a fluid sensing method according to analternative embodiment.

DETAILED DESCRIPTION

FIG. 1A is a fluid dispensing system 30 according to one embodiment. Thefluid dispensing system 30 includes a control module 32 configured towirelessly communicate with a sensor module 34. A fluid dispensingmechanism 36 is coupled to the sensor module 32 and to a fluid container40. The sensor module 34 is coupled inside of the fluid container 40.

The fluid dispensing mechanism 36 receives a command from the controlmodule 32 to dispense fluid from the fluid container 40 through thefluid line 42 at a particular flow rate. The dispensing mechanism 36then forces fluid from the fluid container 40 through the fluid line 42.The sensor module 34 is positioned within the fluid container 40 to beable to sense a flow rate of the fluid from the fluid container 40, orto sense a parameter of the fluid from which the flow rate of the fluidcan be computed. The sensor module 34 does not receive power from awired connection or from a battery. Instead, the sensor receives powerfrom the control module 32 wirelessly. The control module 32 is coupledto the sensor module 34 by near field communication (NFC). The controlmodule 32 therefore transmits a wireless signal to the sensor module 34.The sensor module 34 receives the signal from the control module andharvests energy from the electric field of the signal. The energyharvested from the wireless signal is the power supply by which thesensor module is powered.

Once the sensor module 34 receives power from the control module 32, thesensor module 34 begins to monitor the flow rate of fluid from the fluidcontainer 40. The sensor module 34 then transmits flow rate datawirelessly to the control module 34. The control module 34 receives theflow rate data and compares the flow rate data to the expected flow ratefrom the container. If the flow rate data is different than the expectedflow rate, then the control module 32 causes the dispensing mechanism 36to increase or decrease the flow of fluid from the fluid container 40 asthe case may be. The control module 32 can also cause the dispensingmechanism to cease delivery of the fluid according to flow rate data.

If the flow rate data received from the sensor module 34 agrees with theexpected flow rate within an acceptable tolerance range, then thecontrol module 32 does not cause the fluid dispenser 36 to adjust theflow of fluid from the fluid container 40. In this way a feedback loopis established to continuously monitor and adjust the flow rate of thefluid from the fluid container 40.

The fluid dispensing system 30 of FIG. 1A does not suffer from thedrawbacks of many previous systems. The sensor module 34 can be placeddirectly in contact with the fluid within the fluid container 40 or thefluid line 42 because the sensor module is wireless and battery-less. Inmany sensitive fluid dispensing systems 30, a sensor module 34containing a battery cannot be placed directly in the fluid due to therisk of chemicals leaking from the battery.

FIG. 1B is a block diagram of a fluid dispensing system 30 according toone embodiment. In FIG. 1B the sensor module 34 is coupled to an outsideof the fluid container 40. In this configuration the sensor module candetect the flow rate by detecting a strain or deformation in the surfaceof the fluid container 40. The sensor module 34 can also be placed inthe fluid line 42 as shown in FIG. 1C, or on an outer surface of thefluid line 42 as shown in FIG. 1D. Alternatively the sensor module 34can be placed at a junction of fluid lines on or within a connectionstructure connecting two fluid lines 42 or a fluid line 42 and a needle,or a fluid line 42 and the fluid container 40. The sensor module 34detects the flow rate of the fluid directly, or indirectly by detectingpressure, strain, capacitance, or any other suitable fluid parameterfrom which a measure of the flow rate can be obtained.

FIG. 2 illustrates a fluid dispensing system 30 according to oneembodiment. The fluid dispensing system 30 includes a control module 32and a sensor module 34. The sensor module 34 includes an antenna 43coupled to a microcontroller 44. A sensor 45 and a memory 46 are alsocoupled to the microcontroller 44. The control module 32 includes amicrocontroller 47 and an antenna 48.

As described previously, the sensor module 34 is a wireless sensormodule. It does not receive power from a battery or from a wiredconnection. Rather, the sensor module 34 can be placed within the fluidbecause it receives power wirelessly from the antenna 48 of the controlmodule 32. In particular, the microcontroller 47 modulates the antenna48 to emit radiation in the RF spectrum according to known near fieldcoupling transmission protocols. The antenna 43 of the sensor module 34receives the RF radiation from the antenna 48 and transmits the signalto the microcontroller 44 which harvests energy from the radiationreceived by the antenna 43. The energy harvested by the microcontroller44 is used to power the microcontroller 44, the memory 46, the sensor45, and the antenna 43 of the sensor module 34.

The microcontroller 44 receives fluid data from the sensor 45 andconverts it from an analog signal to a digital signal. Themicrocontroller 44 modulates the antenna 43 to transmit the digitalsensing data to the antenna 48. The microcontroller 47 receives thedigital sensing data from the antenna 48. Upon receiving the digitalsensing data from the antenna 48, the microcontroller 47 can regulatethe dispensing mechanism 36 accordingly. If the microcontroller 47receives the flow rate data and determines that the flow rate of thefluid is too high or too low, then the microcontroller 47 can controlthe dispensing mechanism 36 to appropriately adjust the flow of thefluid.

A fluid dispensing system 30 according to FIG. 2 is particularly usefulin the medical fields, in which specific drugs must be dispensed at aspecific rate to a patient. However, the fluid dispensing system 30 canbe used in any other suitable fluid dispensing configuration. Forexample, the fluid dispensing system 30 can be used to dispense fuel ina machine, lubricant to lubricate parts of a machine, chemicals in areaction or deposition chamber, or any other suitable fluid dispensingsystem. The fluid dispensing system 30 can therefore be a medical fluiddispensing system, an automotive fluid dispensing system, a mechanicalfluid dispensing system, an environment fluid dispensing system, anexperimental fluid dispensing system, or any other system in which fluidis dispensed at a controlled rate.

FIG. 3 illustrates a fluid dispensing system 30 according to oneembodiment. In one configuration, the fluid dispensing system 30 of FIG.3 includes a replaceable fluid container 40 placed within a containerslot 50 of the fluid dispensing system 30. When placed within thecontainer slot 50 of the fluid dispensing system 30, the fluid container40 is in connection with the fluid line 42. The fluid dispensing system30, utilizing a dispensing mechanism 37 such as a stepper motor andpiston arrangement, then causes fluid to flow from the fluid container40 through the fluid line 42 to a patient receiving medical treatment.Conveniently, a sensor module 34 is placed within the fluid container40. The fluid container 40 is installed in the container slot 50 in sucha manner that the sensor module 34 is adjacent a control module 32 ofthe fluid dispensing system 30. Because the sensor module 34 is in closeproximity to the control module 32, the control module 32 can transmitRF radiation to the sensor module 34, as described previously. Thesensor module 34 then harvests energy from the RF radiation transmittedby the control module 32. Being thus powered by the control module 32,wirelessly, the sensor module 34 senses the flow rate of the fluidwithin the fluid container 40. The sensor module 34 then transmits theflow rate data to the control module 32. The control module 32 processesthe flow rate data and determines whether the flow rate is too high, toolow, or in a proper state.

The fluid dispensing system 30 also contains a display 52 and inputs 53.The display 52 can display the current flow rate of the fluid so that atechnician standing by can monitor the flow rate. The fluid dispensingsystem 30 can also transmit in a wired manner or in a wireless mannerthe flow rate data to a central database, a remote monitor where anothertechnician can view it, or to any other suitable location which can thenmonitor the flow rate. If the control module 32 determines that amalfunction has occurred or that there is a dangerous flow rate, analert can be signaled both on the display 52 or at a remote monitoringstation or computer. Additionally, a technician standing by can operateinputs 53 to inhibit further dispensation of the fluid, to slow down orto speed up the flow rate, or to perform any other useful or suitablefunction.

In one embodiment, the fluid container 40 and the sensor module 34 areboth disposable. Thus, after the fluid has been dispensed from the fluidcontainer 40, the fluid container 40 is removed from the container slot50 and disposed of properly. A new fluid container 40 with a sensormodule 34 can be placed in the container slot 50 so that further fluidcan be dispensed therefrom.

The sensor module 34 also includes a memory 46 as described previously.The memory 46 can store data regarding the type of fluid container 40that the sensor module 34 is placed in, historical data regarding pastflow rates, software instructions for operation of the sensor module, orany other suitable information. For example, the sensor module 34 canstore data identifying a particular type of fluid container 40 as wellas the specific fluid within the fluid container 40. Thus, when thefluid container 40 is placed within the container slot 50, the controlmodule 32 begins to transmit RF radiation, thereby powering on thesensor module 34. The sensor module 34 thus receiving power thentransmits to the control module 32 data regarding the drug within thefluid container 40. Therefore in one example the sensor module 34transmits to the control module 32 that it is in an insulin fluidcontainer 40. The control module 32 can therefore determine whether theproper fluid container 40 is installed in the container slot 50. If thecontrol module 32 determines that the incorrect drug container is placedwithin the container slot 50, then the control module 32 can prohibitthe fluid dispensing system 30 from dispensing the fluid. The display 52can then display that the wrong fluid is within the container slot 50.This configuration enhances the safety of the fluid dispensing device 30and can save patients from severe injury or even death.

FIG. 4A illustrates a disposable fluid container 40 according to oneembodiment. The disposable fluid container 40 as illustrated in FIG. 4Ahas not been placed within a fluid dispensing system 30. The fluidcontainer 40 includes a sensor module 34 configured to sense the flowrate of a fluid leaving the fluid container 40. FIG. 4B illustrates adrug container according to an alternative embodiment. In FIG. 4B, thesensor module 34 is placed on an outer wall of the fluid container 40.The sensing device of the sensor module 34 is configured not to interactdirectly with the fluid within the fluid container 40, but rather tomeasure the pressure of the walls of the fluid container 40. From thismeasurement an indication of the flow rate can be obtained. For example,if a strain gauge or a pressure sensor of the sensor module 34 detectsthat the walls of the fluid container 40 have expanded slightly, thiscan indicate that the stepper motor of the fluid dispensing system 30has begun to expel fluid from the fluid container 40. When this happens,a slight increase in pressure can be experienced on the walls of thefluid container 40. A very accurate analysis of the flow rate of thedrug from the fluid container 40 can be obtained in this manner.

In one embodiment, the fluid container 40 is made of a plastic materialwhich expands in a known manner under pressure. Alternatively, thesensor module 34 can be embedded within the walls of the fluid container40. Many other suitable configurations of the sensor module 34 within oron the fluid container 40 are possible. All such configurations fallwithin the scope of the present disclosure.

FIG. 5 illustrates a syringe pump 30 according to one embodiment.Syringe pumps are used in medical applications in which a patient is toreceive a specific dose of medication over a specific period of time.Thus the medication is to be dispensed at a particular average flowrate. The syringe pump 30 includes a fluid chamber 40 from which themedication is dispensed. A dispensing mechanism 36 is coupled to apiston which drives fluid from the fluid chamber 40. A sensor module 34is placed on the fluid chamber 40 to measure a flow rate of the fluidfrom the fluid chamber 40. A control module 32 is placed on the syringepump adjacent to the sensor module 34. The syringe pump 30 furtherincludes a display 52 and a user input 53.

When a patient is to receive medication from the syringe pump, thesyringe is placed in the syringe pump 30 such that the sensor module 34,which is attached to the fluid chamber 40 of the syringe, is adjacentthe control module 32. The sensor module 34 and the control module 32are positioned sufficiently close to each other to allow NFC betweenthem. In one embodiment the sensor module 34 is spaced about 5mm or lessfrom the control module 32. The maximum spacing of the sensor module 34and the control module 32 is based in part on the constraints of NFCtechnology and the particular components of the control module 32 andthe sensor module 34.

A fluid line 42 is coupled between the fluid chamber 40 and the patient,terminating in a needle or IV coupled to the patient. A medicaltechnician then enters instructions into the input 53 of the syringepump 30. The control module 32 stores data from the input 53 regardingthe desired time period and flow rate for the dispensation of the fluid.The control module 32 then causes the dispensing mechanism 36, a steppermotor in one example, to begin to drive fluid from the fluid chamber 40through the fluid line 42. The control module 32 also initiates NFC withthe sensor module 34. The sensor module 34 harvests energy from thewireless transmissions of the control module 32 and begins to monitor aflow rate of the fluid from the fluid chamber 40. The sensor module 34transmits flow rate data to the control module 32. The control module 32then causes the dispensing mechanism 36 to adjust the flow rate of thefluid according to the flow rate data received from the sensor module34.

FIG. 6 illustrates an infusion pump 30 according to one embodiment. Theinfusion pump 30 includes an IV bag coupled to a drip chamber 40. Thedrip chamber 40 is further coupled to a fluid line 42 which deliversmedication from the IV bag to a patient. The infusion pump includes adisplay 52 and a user input 53. A sensor module 34 is attached to thedrip chamber 40. A control module 32 is coupled to a clip adjacent thesensor module 34 to enable NFC between the sensor module 34 and thecontrol module 32 as described previously. The control module 34 iscoupled to the infusion pump by a wired connection or by a wirelessconnection.

When a patient is to receive fluid from the infusion pump 30, the IV bagis placed in the infusion pump 30 such that the sensor module 34, whichis attached to the drip chamber 40 of the infusion pump, is adjacent thecontrol module 32. The sensor module 34 and the control module 32 arepositioned sufficiently close to each other to allow NFC between them.In one embodiment the sensor module 34 is spaced about 5mm or less fromthe control module 32. The maximum spacing of the sensor module 34 andthe control module 32 is based in part on the constraints of NFCtechnology and the particular components of the control module 32 andthe sensor module 34.

A fluid line 42 is coupled between the drip chamber 40 and the patient,terminating in a needle or IV coupled to the patient. A medicaltechnician then enters instructions into the input 53 of the infusionpump 30. The control module 32 stores data from the input 53 regardingthe desired time period and flow rate for the dispensation of the fluid.The control module 32 then causes the dispensing mechanism 36 to beginto drive fluid from the fluid chamber 40 through the fluid line 42. Thecontrol module 32 also initiates NFC with the sensor module 34. Thesensor module 34 harvests energy from the wireless transmissions of thecontrol module 32 and begins to monitor a flow rate of the fluid fromthe fluid chamber 40. The sensor module 34 transmits flow rate data tothe control module 32. The control module 32 then causes the dispensingmechanism 36 to adjust the flow rate of the fluid according to the flowrate data received from the sensor module 34.

FIG. 7 illustrates a portable insulin pump 30 according to oneembodiment. The insulin pump 30 is connected to a belt at the waist of apatient. The insulin pump 30 is configured to deliver insulin in acontrolled manner to the patent. The insulin pump 30 includes areplaceable insulin cartridge 40 placed in a cartridge port 50 of theinsulin pump 30. The insulin cartridge 40 is further coupled to a fluidline 42 which delivers insulin from the insulin cartridge to a patient.The insulin pump 30 includes a display 52 and a user input 53. A sensormodule 34 is attached to the insulin cartridge 40. The insulin pump 30further includes a control module 32 positioned so that when thereplaceable insulin cartridge 40 is placed within the insulin pump 30,the control module 32 is adjacent the sensor module 34 of the insulincartridge 30 to enable NFC between the sensor module 34 and the controlmodule 32 as described previously. The control module 34 is coupled tothe infusion pump by a wired connection or by a wireless connection.

When a patient is to receive fluid from the insulin pump 30, the insulincartridge 40 is placed in the insulin pump 30. The cartridge 40 and port50 are shaped such that installing the cartridge 40 in the port 50places the sensor module 34 in close proximity to the control module 32.The sensor module 34 and the control module 32 are positionedsufficiently close to each other to allow NFC between them. The patientthen enters input commands to the user input 53. The control module 34causes a dispensing mechanism 36 within the insulin pump 30 to begindispensing insulin from the insulin cartridge 40. The insulin flows fromthe insulin cartridge 40 through the fluid line 42 and into the patient.A medical technician then enters instructions into the input 53 of theinfusion pump 30. The control module 32 also initiates NFC with thesensor module 34. The sensor module 34 harvests energy from the wirelesstransmissions of the control module 32 and begins to monitor a flow rateof the insulin from the insulin cartridge 40. The sensor module 34transmits flow rate data to the control module 32. The control module 32then causes the dispensing mechanism 36 to adjust the flow rate of theinsulin according to the flow rate data received from the sensor module34.

FIG. 8 illustrates fluid dispensing system 30 according to oneembodiment. The fluid dispensing system 30 includes a syringe 40, an IVconnector 51, and a fluid line 42. The IV connector 51 connects thesyringe 40 to the fluid line 42. A sensor module 34 is placed within theIV connector 51. A control module 32, not pictured in FIG. 8, can becoupled to the outside of the IV connector 51 at an appropriate distanceto be able to initiate NFC with the sensor module 34 as describedpreviously. The control module 32 is connected to a dispensing mechanismthat forces fluid from the syringe 40, through the IV connector andfluid line 42 to a patient. As described previously, the control module32 also initiates NFC with the sensor module 34. The sensor module 34harvests energy from the wireless transmissions of the control module 32and begins to monitor a flow rate of the fluid from the syringe 40. Thesensor module transmits flow rate data to the control module 32. Thecontrol module 32 then causes the dispensing mechanism 36 to adjust theflow rate of the fluid according to the flow rate data received from thesensor module 34.

While the sensor has been depicted in various positions attached tovarious components of fluid dispensing systems 30, the sensor module 34can be placed in any suitable position. The sensor module 34 can besmall enough to fit within very small fluid lines and structures. Thesensor module 34 can be on the outside or the inside of the variousstructures. The sensor module 34 can even be placed within the wall of afluid line 42 or fluid chamber 40.

FIG. 9 illustrates a sensor module 34 according to one embodiment. Thesensor module 34 includes an antenna 43 and a sensor 45 coupled to anASIC 54. In particular the antenna 43 is coupled to energy harvestingcircuitry 57 of the ASIC. The energy harvesting circuitry can includerectifier and clock circuitry which performs a function of harvestingenergy from the radiation received by the antenna 43. The energyharvesting circuitry 57 is further coupled to a voltage regulator 58.The voltage regulator 58 regulates the voltage generated by harvestingenergy from the antenna 43. The voltage regulator 58 can also includepower-on reset functionality. An RF transceiver 56 is coupled to theantenna circuitry 43 through the energy harvesting circuitry 57. The RFtransceiver 56 is also coupled to a controller 44. The sensor 45 iscoupled to the controller 44 through a sensor interface 60. A memory 46and a temperature sensor 62 are also coupled to the controller 44.

The controller 44 modulates the RF transceiver 56 so that the RFtransceiver 56 can transmit, through the antenna 43, signals relating tosensor data, as described previously. The controller 44 can also receivedigital signals from the control module 32 through the antenna 43 andthe RF transceiver 56.

The sensor module 34 is configured to be coupled to a control module 32by NFC. In particular, the antenna 43 receives wireless signals from thecontrol module 32. The energy harvesting circuitry 56 harvests energyfrom the wireless signals in a known manner. The voltage regulator 58regulates the voltage generated from the wireless signals to provide asteady voltage supply to the rest of the components of the sensor module34. When the sensor module 34 is being powered by the control module 32,the sensor 45 senses the flow rate or other suitable parameter of thefluid in which it is placed. The sensor 45 passes a sensor signal to thesensor interface circuitry 60 which passes the signal to the controller44. The controller 44 processes the sensor signal. In one embodiment thecontroller 44 includes analog to digital conversion circuitry to convertthe sensor signal to a digital sensor signal. The controller 44 thencauses the transceiver 57 to modulate the antenna 43 to transmit thedigital sensor data to the control module 32. The controller 44 canstore sensor data in the memory 46. The memory 46 can also containsoftware instructions for operation of the sensor module 34. The memory46 can also include fluid identification data which identifies the typeof fluid in a fluid container 40 in which the sensor module 34 is to beplaced. The controller 44 can transmit the fluid identification data tothe control module 32.

The temperature sensor 62 can be utilized to further increase theaccuracy of the flow rate data gathered by the controller 44. Inparticular, pressure and strain and capacitance measurements of thesensor 45 can vary according to the temperature. In order to control forthe effects of temperature variation, the controller 44 receives atemperature measurement from the temperature sensor 62. The temperaturesensor 62 can be a bandgap sensor or any other suitable sensor. Thecontroller 44 receives sensor data from the sensor 45. The controller 44calculates a flow rate or a pressure or strain, or any other suitableparameter, based on signals received from the sensor 45. The controller44 can take into account the temperature data received from thetemperature sensor 62 and compute or estimate an accurate determinationof the flow rate or other desired parameter, and output such data to theRF transceiver 56, which then transmits the data through the antenna 43.The particular configuration shown in FIG. 9 is given only by way ofexample. Many other components can be used and other configurations ofthe components shown can also be made. Such other configurations andcomponents fall within the scope of the present disclosure.

FIG. 10A illustrates a sensor module 34 according to one embodiment. Thesensor module 34 includes a coil antenna 43 positioned on a substrate63. A strain gauge 45 is also positioned on the substrate 63. The straingauge includes two resistors R+ and two resistors R−. The resistors arefor example piezo electric resistors having resistances that changeunder stress or strain. Ten electrical contacts 64 are positioned on thesubstrate 63. The resistors R+, R− and the antenna coil 43 are coupledbetween the contacts 64. The contacts 64 are configured to connect anASIC 54 to the antenna coils 43 and the resistors R+, R−.

In FIG. 10B an ASIC 54 has been placed on the substrate 63 in contactwith the electrical contacts 64. When the ASIC 54 is electricallyconnected to the contacts 64, the four resistors R+, R− are connected ina bridge configuration. The ASIC 54 can monitor the resistances of theresistors R+, R−. By monitoring the resistances of the resistors 64, ameasurement of strain in the resistors R+, R− can be obtained. From thestrain measurement, the flow rate of a fluid can be obtained.

The sensor module 34 of FIG. 10B can be implemented in asilicon-on-plastic configuration. The antenna coil 43 and the straingauge 45 can be formed on a plastic or flex substrate 63. The ASIC 54 isalso placed on the plastic or flex substrate 63. Contacts 64electrically connect the antenna coil 43 and the strain gauge 45 to theASIC 54. The antenna 43 and the strain gauge 45 can be formed byprinting metal and piezo-resistive materials onto the substrate 63 or inany other suitable manner. Methods and structures for implementing NFCantennas are well known in the art and are not detailed here. Someexamples of how to implement an antenna 43 are shown in US PatentApplication No. 2011/0148720 and 2008/0081631 which are herebyincorporated by reference.

Methods and structures for forming strain gauges are likewise well knownin the art and are not detailed here. For example, it is well known thatstrain gauges can be formed using piezoresistive resistor bridges,optical strain gauges, and many other suitable methods and structures.One example of a strain gauge is given in US Patent Application No.2007/0240524 which is incorporated herein by reference.

The antenna 43 is energized when it receives radiation from an antenna48 of a control module 32. The radiation is in the radio frequencyspectrum and the ASIC 54 contains circuitry which harvests energy fromthe radiation received by the antenna 43. The ASIC 54 is thus powered bythe antenna 43. The ASIC 54 can then monitor the strain gauge 45 bywhich flow rate or other fluid parameters can be measured. The ASIC 54,after ascertaining the flow rate, then modulates the antenna 43 totransmit the flow rate data or other suitable sensor data to the antenna48 of the control module 32 as described previously. In an alternativeembodiment, RF transceiver 56 and energy harvesting circuitry 57 can beformed on separate substrates or in separate integrated circuit dice onthe substrate 63 and coupled to the ASIC 54.

In one embodiment the antenna 43 is coupled to the ASIC such that themetal of the antenna is between the ASIC and the plastic or flexsubstrate. The metal of the strain gauge is not in contact with thefluid. But rather, the plastic or flex substrate is in contact with thefluid and deforms according to the strain or pressure in the fluid andthereby causes the printed metal of the strain gauge to deform as well.This deformation of the strain gauge changes the resistance of thestrain gauge. The ASIC therefore monitors the resistance of the straingauge, or strain gauges in a bridge formation, and can calculate strain,pressure, flow rate, or any other suitable parameters to be measuredbased on this change in resistances of the resistors R+, R− of thestrain gauge or strain gauges.

FIG. 11 is a cross section of the sensor module 34 taken along sectionlines 11 of FIG. 10B according to one embodiment. The ASIC 54 is coupledto the substrate 63 by an adhesive underfill 67. The ASIC 54 iselectrically coupled to the contacts 64 by solder balls 68. The sensormodule 34 includes a cap 66 placed on the substrate 63. The cap 66 isconfigured to seal the ASIC, stain gauge 45, and antenna 43 in aprotected cavity defined by the cap 66 and the substrate 63. The ASIC54, antenna 43, and strain gauge 45 are thereby protected fromcontamination by the fluid in which the sensor module is placed or fromother environmental contaminants as well as physical damage.

In FIG. 11, the antenna coil 43 is visible on the substrate 63 as wellas two contacts 64 coupled to the antenna coil 43. The strain gauge 45is not visible in FIG. 11. The sensor module 34 is configured to beplaced within a fluid to be monitored, or on a surface of a fluid line42 or fluid container 40.

The sensor module 34 of FIG. 11 is given only by way of example.Alternative configurations are possible as will be apparent to those ofskill in the art in light of the present disclosure. In particular, thestrain gauge 45, the antenna coil 43, and the ASIC 54 can be placed ondifferent surfaces and in different configurations. Other types ofsensors can be used instead of a strain gauge 45.

FIG. 12 illustrates a control module 32 according to one embodiment. Thecontrol module 32 includes a transceiver 69 coupled to a microcontroller47 and an antenna 48. A USB port 72 is coupled to the microcontroller47. A JTAG port is also coupled to the microcontroller 47.

The microcontroller 47 controls the antenna 48 and thereby causes theantenna 48 to radiate RF radiation to power a sensor module 34 which isadjacent the control module 32. The antenna 48 transmits data andinterrogation signals to the sensor module 34 and receives data from thesensor module 34. The antenna 48 supplies the data received from thesensor module 34 to the microcontroller 47. The microcontroller 47 canthen control the fluid dispensing mechanism 36 of a fluid dispensingsystem 30.

The USB port 72 and the JTAG port 70 can be utilized to program thecontrol module 32, debug the control module 32, and receive data fromthe control module 32. The control module 32 of FIG. 12 can be packagedin an integrated circuit package and installed in a fluid dispensingsystem 30 adjacent a sensor module 34 as described previously.

FIG. 13 is a block diagram of a sensor module 34 according to oneembodiment. The sensor module 34 includes an antenna 43 coupled to anASIC 54. The ASIC 54 is further coupled to a MEMS fluid sensor 45.

As described previously, the sensor module 34 is placed in a fluidcontainer or in a fluid channel such as a drug cartridge or IV line. Thesensor module 34 is adjacent a control module 32. The antenna 43receives electromagnetic radiation from the control module 32. The ASIC54 includes energy harvesting circuitry which harvests energy from theradiation received by the antenna 43. The ASIC 54 also includestransceiver circuitry for operating the antenna 43. The ASIC 54 ispowered by the energy harvested from the radiation received by theantenna 43. The MEMS sensor 45 detects a parameter of the fluid, such asa flow rate, a pressure, or other suitable parameter. The ASIC 54receives a sensor signal from the sensor 45 indicative of the fluidparameter. The ASIC 54 then modulates the antenna 43 to transmit fluiddata to the control module 32.

FIG. 14 is a simplified cross section of a control module 34 accordingto one embodiment. The sensor module 34 includes an ASIC 54 formed in afirst substrate and a MEMS sensor 54 formed in a second substrate andcoupled to the first substrate. The sensor module 54 of FIG. 3 can beencapsulated in an integrated circuit package suitable for being placedin a fluid. The packaging can include inlets to allow fluid to contactthe MEMS sensor 54.

FIG. 15 is a cross section of a sensor module 34 according to oneembodiment. The sensor module 34 includes a fluid channel 74 definedbetween a first substrate 64 and a second substrate 66. Two capacitivefluid sensors 45 are placed within the channel 74. Each capacitive fluidsensor 45 includes a respective top capacitor plate 76 a, 76 b and arespective bottom capacitor plate 78 a, 78 b. The top capacitor plates76 a, 76 b are coupled to respective flexible members 80 a, 80 b whichallow the top capacitor plates 76 a, 76 b of each capacitive fluidsensor 45 to deflect nearer to or further from the respective bottomcapacitor plates 78 a, 78 b of the capacitive fluid sensors 45.

When the sensor module 34 is placed in a flowing fluid, fluid flowsthrough the channel 74. The pressure of the fluid in the channel isinfluenced by the flow rate of the fluid through the channel. As thepressure in the channel 74 decreases, the top capacitor plates 76 a, 76b of the capacitive fluid sensors 45 deflect further from the bottomcapacitor plates 78 a, 78 b and the capacitance between the platesdecreases, thereby giving an indication of the pressure and the flowrate in the channel 74. In some circumstances the fluid may have a firstpressure P1 at the entrance of the channel 74 and a second pressure P2,which can be taken into account by having two capacitive pressuresensors 45.

FIG. 16 is a flow diagram of a method for controlling the flow rate of afluid according to one embodiment. At 100, near field coupling isinitiated between a sensor module 34 and a control module 32. Inparticular the control module 32 transmits electromagnetic radiation,for example RF radiation. The sensor module 34 receives the RF radiationand harvests energy therefrom. At 102 the sensor 45 of the sensor module34 senses the flow rate of the fluid in which the sensor module 34 isplaced. At 104 the sensor module 34 transmits flow rate data to thecontrol module 32. The control module 32 receives the flow rate data andcompares the flow rate data to an expected flow rate value. At 106 thecontrol module 32 adjusts the flow rate of the fluid by controlling afluid dispensing mechanism 36. In this manner the flow rate of the fluidcan be controlled in a precise manner.

FIG. 17 is a flow diagram of a method for controlling the flow rate of afluid according to an alternative embodiment. At 108, near fieldcoupling is initiated between a sensor module 34 and a control module32. In particular the control module 32 transmits electromagneticradiation, for example RF radiation. The sensor module 34 receives theRF radiation and harvests energy therefrom. The control module 32transmits a request for fluid ID. At 110 the sensor module 34 transmitsthe fluid ID code of the fluid in which the sensor module 34 is placed.

At 112 the control module 32 checks the fluid ID code to ensure thecorrect fluid has been provided, prior to the fluid flowing. This can bedone by the control module 32 transmitting an interrogation signal tothe sensor module 34. In upon receiving the interrogation signal, thesensor module 34 retrieves the fluid ID code from memory 46 andtransmits the fluid ID code to the control module 32. If the fluid IDcode does not correspond to the expected fluid ID code, the controlmodule 32 disables the fluid dispensing mechanism 36 and prevents fluidfrom flowing. This can be extremely useful in preventing the wrong drugfrom being administered to a patient. If the fluid ID code is correctthen the control module initiates the fluid dispensing mechanism 36 tobegin dispensing the fluid. At 116 the sensor module senses the flowrate of the fluid. At 118 the sensor module 34 transmits flow rate datato the control module 32. The control module 32 receives the flow ratedata and compares the flow rate data to an expected flow rate value. At120 the control module 32 adjusts the flow rate of the fluid bycontrolling a fluid dispensing mechanism 36. In this manner the flowrate of the fluid can be controlled in a precise manner.

While specific embodiments have been described in relation to thefigures, other embodiments and configurations are possible. For example,in one embodiment a cost-effective highly accurate biocompatible sensormodule 34 with an integrated temperature sensor at the point ofadministration, subcutaneously, capable of harvesting ambient energy ofsome type, for example of heat, kinetic energy, solar energy, RF energy,or any other suitable energy to power itself and communicate via an RFprotocol, for example ZigBee® protocol, BTLE protocol, or RFID protocol,with the main system microcontroller of a fluid dispensing system 30provides accurate flow rates and dose sizes when used in a medicalapplication. For an infusion pump, this could be at the end of theinfusion set, while in an auto-injector or syringe pump it could be inthe fluid container 40 volumetric chamber, where a unique identifiercommunicated over the RF protocol to the microcontroller 47 wouldconfirm that the correct drug was being administered, and enable ordisable the operation of the pump or injector accordingly.

An added benefit of this mechanism would be to eliminate the possibilityof competitors cloning the cassette, or patients unintentionally usingcounterfeit drugs. The data could also be encrypted, as is currentlyimplemented in near field communication readers and tags, to ensurecommunication integrity. The data received could be logged for laterdownload as well as used for alarms, such as a free-flow alarm, animproper flow of fluid alarm, an occlusion alarm, an air-in-line alarm,or a dose limit or a Bolus limit exceeded alarm, an empty reservoiralarm, a no reservoir alarm, and a drug mismatch alarm to reduce oreliminate harmful errors. In one embodiment, a sensor module 34 wouldsurvive all forms of sterilization, whether it was steam, gammaradiation, or other type of sterilization.

Upon the initial use of the hose or drug container to be used with theinfusion pump, the RF interface would provide power to the sensor system34, authenticate that the drug is compatible with the pump by reading apre-stored unique ID stored in the memory 46 of the sensor module 34,and then proceed to synchronize the sensor with the RTC from the pump bywriting the initial timestamp to the memory 46, which would in turnpower up the low power microcontroller 44, start the internal RTC, andthen put the system to sleep. After the initial synchronization process,any time an injection is performed, the pump would wake up the sensorover the RF interface via an interrupt on the dual-interface EEPROM 46.The microcontroller 44 would interrogate the sensor 45 and providereal-time feedback over RFID to the main microcontroller 47, allowingfor more accurate dosing.

Using a thinned integrated circuit die or dies on flexible plastic forthe sensor module 34 allows strain measurement and pressure derivativefor various containers 40 and materials. This can be powered solely bythe electric field from a control module 32, for example a DEMO-CR95HF-Aboard. Use of an integrated circuit die allows for a small solutionsize. The control module 32 and the sensor module 34 can usemultiprotocol contactless transceiver IC operating in HF at 13.56 MHz,which can use a wide range of embedded RF applications. There are manysuitable RF reader/writer designs for portable and stationary systems.Such a system 30 can be used in a broad range of applications, includingcomputer applications, peripheral applications, consumer applications,industrial applications, healthcare applications, and meteringapplications. This can be used in compliance with standards such as ISO15693, ISO 14443A/B and NFC ISO 18092. In one embodiment, the sensormodule 34 is placed within an inch of the control module 32. The closerthe sensor module 34 is to the control module 32, the more power thesensor module 34 can harvest from the radiation from the control module32. Any suitable distance can be used which allows the sensor module 34to harvest energy sufficient to power itself from the radiationtransmitted by the control module 32.

In one embodiment, the ASIC 54 has an analog-to-digital converter inaddition to energy harvesting circuitry. While a low powermicrocontroller 44 can be implemented in the ASIC, in one embodiment theASIC does not have a microcontroller 44 but simply an analog-to-digitalconverter, suitable memory storage, and energy harvesting circuitry inaddition to other circuitry allowing communication between the controlmodule 32, the antenna 43, and the sensor 45. The sensor 45 can be anysuitable sensor, including a sensor printed on a substrate, a MEMSsensor, or any other suitable sensor.

The various embodiments described above can be combined to providefurther embodiments. All of the U.S. patents, U.S. patent applicationpublications, U.S. patent applications, foreign patents, foreign patentapplications and non-patent publications referred to in thisspecification and/or listed in the Application Data Sheet areincorporated herein by reference, in their entirety. Aspects of theembodiments can be modified, if necessary to employ concepts of thevarious patents, applications and publications to provide yet furtherembodiments.

These and other changes can be made to the embodiments in light of theabove-detailed description. In general, in the following claims, theterms used should not be construed to limit the claims to the specificembodiments disclosed in the specification and the claims, but should beconstrued to include all possible embodiments along with the full scopeof equivalents to which such claims are entitled. Accordingly, theclaims are not limited by the disclosure.

1. A system comprising: a fluid container; a fluid dispenser coupled tothe fluid container and configured to cause the fluid container todispense fluid; a sensor module coupled to the fluid container andconfigured to measure a fluid parameter of the fluid and to transmit themeasured fluid parameter as data; and a control module coupled to thefluid dispenser and to the sensor module, the control module configuredto power the sensor module, and to receive the fluid data from thesensor module by near field coupling.
 2. The system of claim 1 whereinthe sensor module includes: a sensor configured to sense the fluidparameter; and an integrated circuit die coupled to the sensor andconfigured to receive an analog signal from the sensor, the analogsignal being indicative of the fluid parameter.
 3. The system of claim 2wherein the integrated circuit die includes a memory.
 4. The system ofclaim 3 wherein the memory stores fluid identity data identifying thefluid in the fluid container and wherein the sensor module is configuredto transmit the fluid identity data to the control module.
 5. The systemof claim 4 wherein the control module controls a flow rate of the fluidbased in part on the fluid identity data.
 6. The system of claim 2wherein the integrated circuit die includes an analog-to-digitalconverter configured to convert the analog signal to a digital signal.7. A method comprising: dispensing fluid from a fluid container;sensing, in a sensor module coupled to the fluid container, a fluidparameter of the fluid; powering the sensor module by near fieldcoupling with a control module adjacent to the sensor module;transmitting the fluid parameter as data indicative of the fluidparameter from the sensor module to the control module; and controllinga flow rate of the fluid based in part on the fluid data.
 8. The methodof claim 7 comprising transmitting a fluid identification code from thesensor module to the control module.
 9. The method of claim 8 whereinthe fluid identification code is stored in a memory of the sensormodule.
 10. The method of claim 9 comprising: receiving the fluididentification code in the control module; and dispensing the fluid onlyif the fluid identification code corresponds to an expected fluididentification.
 11. The method of claim 7 wherein the fluid parameter isa pressure of the fluid.
 12. The method of claim 7 wherein the fluidparameter is the flow rate of the fluid.
 13. A device comprising: afluid sensor configured to sense a fluid parameter and to output ananalog fluid signal indicative of the fluid parameter; and an integratedcircuit die packaged with the fluid sensor and electrically coupledthereto, the integrated circuit die configured to receive the analogfluid signal, to convert the analog fluid signal to a digital fluidsignal, to be powered by near field coupling with an adjacent controlmodule, and to output the digital fluid signal to the control module.14. The device of claim 13 comprising an antenna coupled to theintegrated circuit die and packaged therewith, the antenna beingconfigured to receive an RF signal from the control module.
 15. Thedevice of claim 14 comprising: a first substrate, the antenna beingpositioned on the first substrate; and a second substrate, the fluidsensor being positioned on the second substrate, the integrated circuitdie being positioned between the first and second substrates.
 16. Thedevice of claim 15 wherein the first and second substrates are glass.17. The device of claim 16 wherein the first and second substrates areflex substrates.
 18. The device of claim 13 comprising a temperaturesensor coupled to the integrated circuit die.